We have developed a simple method for fabricating robust and low noise glass nanopore electrodes with pore size 10±5 nm to detect single molecules.β-Cyclodextrin was used as model compound for characterization.I...We have developed a simple method for fabricating robust and low noise glass nanopore electrodes with pore size 10±5 nm to detect single molecules.β-Cyclodextrin was used as model compound for characterization.In 1.0 mol/L NaCl solution,the molecules generated current pulses of 2-5 pA with noise level less than 0.8 pA.A slide mode and a plug mode were suggested for the way ofβ-cyclodextrin single molecule moving into the glass nanopores.展开更多
Biosensors featuring single molecule detection present huge opportunities as well as challenges in food safety inspection,disease diagnosis,and environmental monitoring.Single-molecule detection is largely lacking of ...Biosensors featuring single molecule detection present huge opportunities as well as challenges in food safety inspection,disease diagnosis,and environmental monitoring.Single-molecule detection is largely lacking of high enough activity,precision molecule selectivity,and understanding in the exact operating mechanism.Single-atom catalysts(SACs),especially those metals-nitrogen-carbon that mimic the natural metalloenzyme structure,and with well-defined metal atom bond configurations,high level of molecular selectivity,and easy fabrication,endow single molecule detections with practical-use feasibilities.The recent advances in single-atom catalysts also present new pathways in the key mechanism understandings.In this short review,we will first visit the brief history and advantages of SACs that have been explored only recently for molecule-scale biosensors,where they are analogous and also differentiated from those nanozymes and natural metalloenzymes.Their applications in electrochemical,photochemical,and photoelectrochemical sensors are then discussed comprehensively by focusing on the different molecule-scale sensing modes in achieving local coordination-modulated signal amplifications.Finally,we identify new opportunities and challenges faced by these SACs-based single molecule detections in the further development of biosensors.展开更多
In recent years, bio-nanopore and solid-state nanopore have been greatly improved for molecule bio-sensing. Whereas, the development of this scientific field seems to have encountered a bottleneck due to their respect...In recent years, bio-nanopore and solid-state nanopore have been greatly improved for molecule bio-sensing. Whereas, the development of this scientific field seems to have encountered a bottleneck due to their respective limitations. The small pore size of the former impedes the detection of large single molecule, and the latter is difficult to achieve similar accuracy and functional control. DNA origami plays a novel role to bring more opportuni- ties for the development of nanopore technology since it is relatively easy to synthesize and modify. This review mainly focuses on introducing the DNA origami nanopore fabrication methods, characterization and application. Meanwhile, the challenges in the present DNA origami nanopore research are also discussed.展开更多
基金support from the National Natural Science Foundation of China(No. 20575062) The Graduate Innovation Fund of USTC
文摘We have developed a simple method for fabricating robust and low noise glass nanopore electrodes with pore size 10±5 nm to detect single molecules.β-Cyclodextrin was used as model compound for characterization.In 1.0 mol/L NaCl solution,the molecules generated current pulses of 2-5 pA with noise level less than 0.8 pA.A slide mode and a plug mode were suggested for the way ofβ-cyclodextrin single molecule moving into the glass nanopores.
基金Prof.Z.Kou acknowledges the financial support of the Fundamental Research Funds for the Central Universities(Grant No.40120631)Natural Science Foundation of Hubei Province(Grant No.2021CFB007)+2 种基金National Natural Science Foundation of China(Grant No.52202291)the support.Prof.J.Wang thanks the support by the Singapore Ministry of Education,and the National Research Foundation(NRF)research conducted at the National University of Singapore(Tier 1,A-8000186-01-00,and CRP NRF-CRP26-2021-0003).
文摘Biosensors featuring single molecule detection present huge opportunities as well as challenges in food safety inspection,disease diagnosis,and environmental monitoring.Single-molecule detection is largely lacking of high enough activity,precision molecule selectivity,and understanding in the exact operating mechanism.Single-atom catalysts(SACs),especially those metals-nitrogen-carbon that mimic the natural metalloenzyme structure,and with well-defined metal atom bond configurations,high level of molecular selectivity,and easy fabrication,endow single molecule detections with practical-use feasibilities.The recent advances in single-atom catalysts also present new pathways in the key mechanism understandings.In this short review,we will first visit the brief history and advantages of SACs that have been explored only recently for molecule-scale biosensors,where they are analogous and also differentiated from those nanozymes and natural metalloenzymes.Their applications in electrochemical,photochemical,and photoelectrochemical sensors are then discussed comprehensively by focusing on the different molecule-scale sensing modes in achieving local coordination-modulated signal amplifications.Finally,we identify new opportunities and challenges faced by these SACs-based single molecule detections in the further development of biosensors.
文摘In recent years, bio-nanopore and solid-state nanopore have been greatly improved for molecule bio-sensing. Whereas, the development of this scientific field seems to have encountered a bottleneck due to their respective limitations. The small pore size of the former impedes the detection of large single molecule, and the latter is difficult to achieve similar accuracy and functional control. DNA origami plays a novel role to bring more opportuni- ties for the development of nanopore technology since it is relatively easy to synthesize and modify. This review mainly focuses on introducing the DNA origami nanopore fabrication methods, characterization and application. Meanwhile, the challenges in the present DNA origami nanopore research are also discussed.
